Towards optimal wing design for novel airframe and propulsion opportunities
Towards optimal wing design for novel airframe and propulsion opportunities
Strict sustainability objectives have been established for the upcoming generation of aircraft. A promising innovative airframe concept is the ultra-high-aspect-ratio Strut-Braced-Wing Aircraft (SBWA). Hydrogen-powered concepts are strong candidates for sustainable propulsion. The study investigates the influence of Liquid Hydrogen (LH2) propulsion on the optimal wing geometry of medium-range SBWA for minimum-cost and minimum-emission objectives. Multiobjective optimizations are performed in two optimization frameworks of differing fidelity for both kerosene- and LH2-propelled SBWA concepts. Furthermore, a range of Pareto-optimal designs show the changes in the optimized planform for variable weighting of the two objectives. The results show that the differences in the optimal wing geometry between the kerosene- and LH2-powered results for each respective objective function are small. For both aircraft, the minimum-emission objective optimizes for lower fuel burns and hence lower emissions, albeit at an increase in wing structural mass. The minimum-cost objective balances the reductions in structural and fuel masses, resulting in a lighter design at lower aspect ratios. Other wing-shape parameters only have minor contributions. Although the wing aspect ratios for both objectives differ by ca. 50%, the actual changes are only 2.5% in fuel and 1.5% in Direct Operating Cost (DOC). Due to a larger set of design variables used in the higher-fidelity optimizations, further parasite and wave drag reduction opportunities result in increased optimal aspect ratios.
aerostructural optimization, aircraft design, hydrogen, strut-braced wing, ultra-high-aspect-ratio wing
Wahler, Nicolas F.M.
b8ee2159-db14-4859-8c36-47262d7aa4b7
Elham, Ali
676043c6-547a-4081-8521-1567885ad41a
23 May 2025
Wahler, Nicolas F.M.
b8ee2159-db14-4859-8c36-47262d7aa4b7
Elham, Ali
676043c6-547a-4081-8521-1567885ad41a
Wahler, Nicolas F.M. and Elham, Ali
(2025)
Towards optimal wing design for novel airframe and propulsion opportunities.
Aerospace, 12 (6), [459].
(doi:10.3390/aerospace12060459).
Abstract
Strict sustainability objectives have been established for the upcoming generation of aircraft. A promising innovative airframe concept is the ultra-high-aspect-ratio Strut-Braced-Wing Aircraft (SBWA). Hydrogen-powered concepts are strong candidates for sustainable propulsion. The study investigates the influence of Liquid Hydrogen (LH2) propulsion on the optimal wing geometry of medium-range SBWA for minimum-cost and minimum-emission objectives. Multiobjective optimizations are performed in two optimization frameworks of differing fidelity for both kerosene- and LH2-propelled SBWA concepts. Furthermore, a range of Pareto-optimal designs show the changes in the optimized planform for variable weighting of the two objectives. The results show that the differences in the optimal wing geometry between the kerosene- and LH2-powered results for each respective objective function are small. For both aircraft, the minimum-emission objective optimizes for lower fuel burns and hence lower emissions, albeit at an increase in wing structural mass. The minimum-cost objective balances the reductions in structural and fuel masses, resulting in a lighter design at lower aspect ratios. Other wing-shape parameters only have minor contributions. Although the wing aspect ratios for both objectives differ by ca. 50%, the actual changes are only 2.5% in fuel and 1.5% in Direct Operating Cost (DOC). Due to a larger set of design variables used in the higher-fidelity optimizations, further parasite and wave drag reduction opportunities result in increased optimal aspect ratios.
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aerospace-12-00459
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Accepted/In Press date: 20 May 2025
Published date: 23 May 2025
Keywords:
aerostructural optimization, aircraft design, hydrogen, strut-braced wing, ultra-high-aspect-ratio wing
Identifiers
Local EPrints ID: 504115
URI: http://eprints.soton.ac.uk/id/eprint/504115
ISSN: 2226-4310
PURE UUID: 252bb106-eb88-404e-8c10-fac1542b7ab7
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Date deposited: 26 Aug 2025 16:46
Last modified: 26 Aug 2025 16:48
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Author:
Nicolas F.M. Wahler
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